FI72614C - Optically conductive element and method for its manufacture. - Google Patents

Description

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(21) Patent application - Patentansökning 773328 (22) Application date - Ansöknlngsdag 07.11.77 (H) (23) Starting date - Glltighetsdag 07- 1 1 -77 (41) Publication - Blivit offentlig 10.05.78

National Board of Patents and Registration Date of display and publication—

Patent-OCh registerstyrelsen '' Ansökan utlagd och utl.skriften publicerad 27.02.87 (86) Kv. application - Int. ansökan (32) (33) (31) Privilege requested - Begärd priority 09.11.76 Denmark-Danmark (DK) 5053/76 (71) Act concerning the Nordic Cable and Cable Manufacturing, La Cours V / e j 7,

KcSbenhavn, Denmark-Danmark (DK) (72) Axel Andersen, Gentofte, Poul Ursin Knudsen, Hellerup,

Knud Bundgaard Jensen, Skodsborg, Denmark-Danmark (DK) (7 * 0 Oy Koister Ab (5 * 0 Optically conductive element and method for its production -Optiskt ledande element och förfarande för dess framstälIning

The present invention relates to an optically conductive element as defined in the preamble of claim 1 and to a method for manufacturing the same.

In the optical element according to the preamble of claim 1, as is known from JA-A-51-103969, the purpose of the strain reduction element is to reduce as much as possible the tensile stresses generated in the optical fiber during extrusion. After extrusion, the optical fiber may be separated from the strain reduction element and the fin, or the optical fiber may be used in conjunction with the strain reduction element by the fin. Length of fin, i.e. the distance between the coating of the optical fiber and the coating of the traction reduction element, here is approximately half the diameter of the coating, and the optical fiber and the traction reduction element run in parallel. Because the optical fibers are a very brittle material, usually glass, the strain reduction element does not substantially reduce the tension of the optical fiber.

It is known to manufacture telecommunication cables with optical fibers, in which case the fibers are arranged in cables in longitudinal cavities which have a considerably larger diameter than the fibers, cf. DE Application Publication 25 28 991.

It is also known to place fibers in corrugations in such cavities. In addition, it is known to glue the fibers in the form of a wave between two plastic strips, which are then wrapped around a fixed support yarn, cf. DE-A-24 24 041. In addition, cables are also known in which the fibers are wound in a helical shape around a soft support layer which is fastened around a fixed support wire, cf. DE-A-24 30 857. The compression of the soft support layer by the optical fibers prevents the optical fibers from being affected by mechanical stresses when the cables are pulled or bent. In particular, efforts are made to avoid traction.

In addition, it is generally known to provide cables with strain-reducing elements, the function of which is to receive the tensile effects on the cable, e.g. during handling and lowering. See. e.g., the aforementioned DE application publication 25 28 991 and DE application publications 23 55 853, 23 55 855 and 24 49 439.

However, in none of the mentioned cable types is the part of the cable containing the optical fiber or optical fibers fixedly connected to the tension reduction element while being in the form of a curve or wave with respect to the tension reduction element.

It is an object of the present invention to provide an optically conductive element which can better prevent mechanical effects such as tension, bending and torsion from lowering the transmission capacity of the optical fibers. It should be noted that a reduction in the transmission capacity of an otherwise flawless optical fiber is to be expected if its optical interior is tightened or deviated from its direction by one or more defects, even with only a very small part of the cable, so that the defects only need to be a millimeter. or microcracking. It is obvious that the greater the risk of the formation of microcracks, the greater the attraction to the optical fiber. The hitherto known structures of telecommunication cables with optical fibers have been used to reduce the magnitude of the tensile stresses of the optical fibers and to prevent their formation, e.g. by helically fixing the fibers to the sheath as described above, possibly together with more or less tension reduction elements.

According to the invention, this object is solved by an optically conductive element, which is characterized by what is set forth in the characterizing part of claim 1.

In the optically conductive element according to the invention, very small forces are applied to the optical fibers themselves, because the fin can easily be distorted. The optical fibers are not subjected to tensile forces as long as the elongation of the tension reduction element can be prevented by smoothing the undulating course.

The invention further relates to a method for manufacturing an optically conductive element according to the invention as set out in claim 5.

The corrugated shape of the optical fiber or optical fibers is achieved, e.g. When the tension reduction element is then de-tensioned and shrunk, the portion or portions of the optical fiber-containing element settle into a wave shape due to the connecting one.

In addition, by means of a suitable design of the extrusion tool, it is possible to make the part or parts of the element containing the optical fibers longer than the part containing the strain reduction element. The optical fibers then settle into a waveform.

The thickness and length of the fin depend in particular on the properties of the coating material, the intended use of the element and the resulting desired waveform. However, the thickness must be such that the fin can withstand the torque applied to it without breaking and the length is greater than the diameter of the coatings so that the resulting waveform can accommodate the excess length of the fiber with respect to the tension reduction element.

It will be appreciated that the fibers in the element, if the fiber contains a plurality of optical fibers, may either be assembled into more or fewer common coatings or the element may have a separate coating 4,72614 for each fiber.

The coating used may be a plastic such as polyethylene, polypropylene, polyvinyl chloride or a polyamide such as polyamide 12. If desired, the coating may consist of a base material and an additional material contained therein, which may be, for example, longitudinal fibers or arbitrarily oriented fibers.

If one or more of the present elements are placed in the sheath, e.g. for the manufacture of a roller cable, without applying traction to them during this step, the waveform of the elements is preserved. It is found that a cable containing such elements withstands tensile stress exceptionally well.

The invention is further illustrated in the drawing, in which Figure 1 shows a side view of a part of an optically conductive element according to the invention, the element comprising an optical fiber and a strain reduction element, Figures 2A and 2B show in section two different embodiments of the element according to the invention. Fig. 2A corresponds to Fig. 1, while Fig. 2B shows a plurality of optical fibers with a common coating, Fig. 3 shows a side view of a part of an optically conductive element according to the invention, the element comprising a central strain reduction element and two corrugated optical fibers, Fig. 4 shows a cross-section AA, Fig. 5 is a cross-sectional view taken along line BB of Fig. 3, Fig. 6 is a cross-sectional view of a telecommunication cable having optically conductive elements according to Fig. 1, and Fig. 7 is a cross-sectional view of a telecommunication cable having two optically conductive elements and Fig. 3.

Figures 1 and 2A show an optical fiber 1, a coating 7, which may be e.g. a plastic material, and a strain reduction element 6 made of a material having a high modulus of elasticity, e.g. a man-made fiber or a metal. The fin 8 contributes to the waveform of the element. The length of the fin is greater than the length of the coating.

Figure 2B shows an embodiment of five optical fibers provided with a common coating having a larger diameter than the coating of the strain reduction element. In these Figs. 5,726 4, the same reference numerals are used as in Figs. 1 and 2A.

Figures 3-5 show an embodiment with two optical fibers 1. Incidentally, the same reference numerals as in Figures 1 and 2 are used. In the figures, the optical fibers are diametrically opposed to the traction reduction element, but in principle they can form any angles therewith.

Figure 6 shows a telecommunication cable having five optically conductive elements of the present type having an optical fiber 1, a strain reduction element 6, a coating 7 and a fin 8. The elements are arranged in a cavity 9 which may be filled with a filler, e.g. Vaseline and which is located in a tubular sheath 10, which may be e.g. a plastic sheath.

Fig. 7 shows a similar telecommunication cable with two optically conductive elements with one optical fiber 1 and one element according to Fig. 3 with two optical fibers 1. The reference numerals are otherwise the same as in Fig. 6.

Claims (5)

6,72614 An optically conductive element comprising one or more optical fibers (1) surrounded by a coating (7) of substantially circular cross-section; and a strain reduction element (6) surrounded by a coating (7) of the same material and circular cross-section, connected to the coating (7) of the optical fiber (s) by a fin (8) having a thickness substantially smaller than that of the coating (7), characterized therein , that the length of the fin (8) is greater than the diameter of the coatings (7) and that the coating surrounding the fiber or fibers (1) is wavy. Optically conductive element according to Claim 1, characterized in that the coating (7) is made of plastic. Optically conductive element according to Claim 2, characterized in that the coating (7) is made of polyethylene, polypropylene, a copolymer, polyvinyl chloride or polyamide. Optically conductive element according to one of the preceding claims, characterized in that the coating (7) consists of a base material and an additional material contained therein. A method of manufacturing an optically conductive element according to claim 1, characterized in that the corrugated shape of the optical fiber or optical fibers (1) is made by applying a tensile stress to the tension reduction element (6) during attachment of the coatings (7).